2014
DOI: 10.1590/s1982-56762014000300001
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Using dynamic diversity to achieve durable disease resistance in agricultural ecosystems

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Cited by 61 publications
(50 citation statements)
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“…The findings described above strongly support the hypothesis that fungal virulence can evolve quickly in agricultural systems (McDonald 2014). Major gene resistance coupled with genetic uniformity of crop plants provides strong selection pressure for pathogen populations to overcome disease resistance, as described above for blackleg resistance of canola.…”
Section: Evolution Of Virulence In Fungal Plant Pathogenssupporting
confidence: 75%
“…The findings described above strongly support the hypothesis that fungal virulence can evolve quickly in agricultural systems (McDonald 2014). Major gene resistance coupled with genetic uniformity of crop plants provides strong selection pressure for pathogen populations to overcome disease resistance, as described above for blackleg resistance of canola.…”
Section: Evolution Of Virulence In Fungal Plant Pathogenssupporting
confidence: 75%
“…annually or every few years) in order to impose disruptive selection on populations of crop pathogens and force them to make trade-offs among traits ( figure 1). This 'dynamic diversity' can be implemented in many ways [67][68][69][70], including improved deployment strategies for resistance genes and resistant cultivars, more frequent turnover of crop varieties that carry different resistance genes, improved deployment strategies for fungicides, more frequent crop rotations that include more species, smaller fields planted to individual crops and growing greater numbers of crop species per unit area under cultivation. The overall objective is to break up the adaptive landscape into smaller units that change on a regular basis to present the corresponding populations of crop pathogens with evolutionary dilemmas that lead to disruptive selection (figure 1).…”
Section: Example 4: Rapid Global Dissemination Of New Clones Carryingmentioning
confidence: 99%
“…They have promoted the discovery of new resistance genes and strongly facilitate their combination in single variety, by genomic selection (e.g., Heffner et al, 2009; Tester and Langridge, 2010). In the future, biotechnologies will allow creating genetically modified new variety with resistance alleles to which the pathogen has never been exposed (McDonald, 2014; Wulff and Moscou, 2014; Figueroa et al, 2016). We could therefore imagine that the deployment of resistance genes into new cultivars will be informed by the knowledge of population genetics of the corresponding avirulence genes and by the dynamics of these virulences in field pathogen populations (Wulff and Moscou, 2014; Figueroa et al, 2016).…”
Section: Pyramiding Disease Resistance Genes To Enhance Their Durabilmentioning
confidence: 99%